On the computational complexity of finding hard tautologies (1212.1789v2)

Abstract: It is well-known (cf. K.-Pudl\'ak 1989) that a polynomial time algorithm finding tautologies hard for a propositional proof system $P$ exists iff $P$ is not optimal. Such an algorithm takes $1^{(k)}$ and outputs a tautology $\tau_k$ of size at least $k$ such that $P$ is not p-bounded on the set of all $\tau_k$'s. We consider two more general search problems involving finding a hard formula, {\bf Cert} and {\bf Find}, motivated by two hypothetical situations: that one can prove that $\np \neq co\np$ and that no optimal proof system exists. In {\bf Cert} one is asked to find a witness that a given non-deterministic circuit with $k$ inputs does not define $TAUT \cap \kk$. In {\bf Find}, given $1^{(k)}$ and a tautology $\alpha$ of size at most $k^{c_0}$, one should output a size $k$ tautology $\beta$ that has no size $k^{c_1}$ $P$-proof from substitution instances of $\alpha$. We shall prove, assuming the existence of an exponentially hard one-way permutation, that {\bf Cert} cannot be solved by a time $2^{O(k)}$ algorithm. Using a stronger hypothesis about the proof complexity of Nisan-Wigderson generator we show that both problems {\bf Cert} and {\bf Find} are actually only partially defined for infinitely many $k$ (i.e. there are inputs corresponding to $k$ for which the problem has no solution). The results are based on interpreting the Nisan-Wigderson generator as a proof system.